/**
* Copyright (c) 2025 Huawei Technologies Co., Ltd.
* This program is free software, you can redistribute it and/or modify it under the terms and conditions of
* CANN Open Software License Agreement Version 2.0 (the "License").
* Please refer to the License for details. You may not use this file except in compliance with the License.
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND, EITHER EXPRESS OR IMPLIED,
* INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT, MERCHANTABILITY, OR FITNESS FOR A PARTICULAR PURPOSE.
* See LICENSE in the root of the software repository for the full text of the License.
*/

/* !
 * \file add.asc
 * \brief
 */

#include <cstdint>
#include <iostream>
#include <vector>
#include <algorithm>
#include <iterator>
#include "acl/acl.h"
#include "kernel_operator.h"

constexpr uint32_t BUFFER_NUM = 2;  //tensor num for each queue

struct AddCustomTilingData
{
    uint32_t totalLength;
    uint32_t tileNum;
};

class KernelAdd {
public:
    __aicore__ inline KernelAdd() {}
    __aicore__ inline void Init(GM_ADDR x, GM_ADDR y, GM_ADDR z, uint32_t totalLength, uint32_t tileNum)
    {
        this->blockLength = totalLength / AscendC::GetBlockNum();
        this->tileNum = tileNum;
        this->tileLength = this->blockLength / tileNum / BUFFER_NUM;
        xGm.SetGlobalBuffer((__gm__ float *)x + this->blockLength * AscendC::GetBlockIdx(), this->blockLength);
        yGm.SetGlobalBuffer((__gm__ float *)y + this->blockLength * AscendC::GetBlockIdx(), this->blockLength);
        zGm.SetGlobalBuffer((__gm__ float *)z + this->blockLength * AscendC::GetBlockIdx(), this->blockLength);
        pipe.InitBuffer(inQueueX, BUFFER_NUM, this->tileLength * sizeof(float));
        pipe.InitBuffer(inQueueY, BUFFER_NUM, this->tileLength * sizeof(float));
        pipe.InitBuffer(outQueueZ, BUFFER_NUM, this->tileLength * sizeof(float));
    }
    __aicore__ inline void Process()
    {
        int32_t loopCount = this->tileNum * BUFFER_NUM;
        for (int32_t i = 0; i < loopCount; i++) {
            CopyIn(i);
            Compute(i);
            CopyOut(i);
        }
    }

private:
    __aicore__ inline void CopyIn(int32_t progress)
    {
        AscendC::LocalTensor<float> xLocal = inQueueX.AllocTensor<float>();
        AscendC::LocalTensor<float> yLocal = inQueueY.AllocTensor<float>();
        AscendC::DataCopy(xLocal, xGm[progress * this->tileLength], this->tileLength);
        AscendC::DataCopy(yLocal, yGm[progress * this->tileLength], this->tileLength);
        inQueueX.EnQue(xLocal);
        inQueueY.EnQue(yLocal);
    }
    __aicore__ inline void Compute(int32_t progress)
    {
        AscendC::LocalTensor<float> xLocal = inQueueX.DeQue<float>();
        AscendC::LocalTensor<float> yLocal = inQueueY.DeQue<float>();
        AscendC::LocalTensor<float> zLocal = outQueueZ.AllocTensor<float>();
        AscendC::Add(zLocal,xLocal, yLocal, this->tileLength);
        outQueueZ.EnQue<float>(zLocal);
        inQueueX.FreeTensor(xLocal);
        inQueueY.FreeTensor(yLocal);
    }
    __aicore__ inline void CopyOut(int32_t progress)
    {
        AscendC::LocalTensor<float> zLocal = outQueueZ.DeQue<float>();
        AscendC::DataCopy(zGm[progress * this->tileLength], zLocal, this->tileLength);
        outQueueZ.FreeTensor(zLocal);
    }

private:
    AscendC::TPipe pipe;
    AscendC::TQue<AscendC::TPosition::VECIN, BUFFER_NUM> inQueueX, inQueueY;
    AscendC::TQue<AscendC::TPosition::VECOUT, BUFFER_NUM> outQueueZ;
    AscendC::GlobalTensor<float> xGm;
    AscendC::GlobalTensor<float> yGm;
    AscendC::GlobalTensor<float> zGm;
    uint32_t blockLength;
    uint32_t tileNum;
    uint32_t tileLength;
};

__global__ __aicore__ void add_custom(GM_ADDR x, GM_ADDR y, GM_ADDR z, AddCustomTilingData tiling)
{
    KERNEL_TASK_TYPE_DEFAULT(KERNEL_TYPE_AIV_ONLY);
    KernelAdd op;
    op.Init(x, y, z, tiling.totalLength, tiling.tileNum);
    op.Process();
}

std::vector<float> kernel_add(std::vector<float> &x, std::vector<float> &y)
{
    constexpr uint32_t blockDim = 8;
    uint32_t totalLength = x.size();
    size_t totalByteSize = totalLength * sizeof(float);
    int32_t deviceId = 0;
    aclrtStream stream = nullptr;
    AddCustomTilingData tiling = {totalLength, 8};
    uint8_t *xHost = reinterpret_cast<uint8_t *>(x.data());
    uint8_t *yHost = reinterpret_cast<uint8_t *>(y.data());
    uint8_t *zHost = nullptr;
    uint8_t *xDevice = nullptr;
    uint8_t *yDevice = nullptr;
    uint8_t *zDevice = nullptr;

    aclInit(nullptr);
    aclrtSetDevice(deviceId);
    aclrtCreateStream(&stream);

    aclrtMallocHost((void **)(&zHost), totalByteSize);
    aclrtMalloc((void **)&xDevice, totalByteSize, ACL_MEM_MALLOC_HUGE_FIRST);
    aclrtMalloc((void **)&yDevice, totalByteSize, ACL_MEM_MALLOC_HUGE_FIRST);
    aclrtMalloc((void **)&zDevice, totalByteSize, ACL_MEM_MALLOC_HUGE_FIRST);

    aclrtMemcpy(xDevice, totalByteSize, xHost, totalByteSize, ACL_MEMCPY_HOST_TO_DEVICE);
    aclrtMemcpy(yDevice, totalByteSize, yHost, totalByteSize, ACL_MEMCPY_HOST_TO_DEVICE);

    add_custom<<<blockDim, nullptr, stream>>>(xDevice, yDevice, zDevice, tiling);
    aclrtSynchronizeStream(stream);

    aclrtMemcpy(zHost, totalByteSize, zDevice, totalByteSize, ACL_MEMCPY_DEVICE_TO_HOST);

    std::vector<float> z((float *)zHost, (float *)(zHost + totalLength));

    aclrtFree(xDevice);
    aclrtFree(yDevice);
    aclrtFree(zDevice);
    aclrtFreeHost(zHost);

    aclrtDestroyStream(stream);
    aclrtResetDevice(deviceId);
    aclFinalize();

    return z;
}

uint32_t VerifyResult(std::vector<float> &output, std::vector<float> &golden)
{
    auto printTensor = [](std::vector<float> &tensor, const char *name) {
        constexpr size_t maxPrintSize = 20;
        std::cout << name << ": ";
        std::copy(tensor.begin(), tensor.begin() + std::min(tensor.size(), maxPrintSize),
            std::ostream_iterator<float>(std::cout, " "));
        if (tensor.size() > maxPrintSize) {
            std::cout << "...";
        }
        std::cout << std::endl;
    };
    printTensor(output, "Output");
    printTensor(golden, "Golden");
    if (std::equal(output.begin(), output.end(), golden.begin())) {
        std::cout << "[Success] Case accuracy is verification passed." << std::endl;
        return 0;
    } else {
        std::cout << "[Failed] Case accuracy is verification failed!" << std::endl;
        return 1;
    }
    return 0;
}

int32_t main(int32_t argc, char *argv[])
{
    constexpr uint32_t totalLength = 8 * 2048;
    constexpr float valueX = 1.2f;
    constexpr float valueY = 2.3f;
    std::vector<float> x(totalLength, valueX);
    std::vector<float> y(totalLength, valueY);

    std::vector<float> output = kernel_add(x, y);

    std::vector<float> golden(totalLength, valueX + valueY);
    return VerifyResult(output, golden);
}